Cutting machine



Dec. 4, 1945. G. o. LANGENBERG l 2,390,375

CUTTING MACHINE Filed Aug. s, 1944 2 sheets-sheet' 2 /m/EA/roz:

GEORGE O. amsn/airs;

Patented Dec. 4, 1945 UNITED STATES PATENT o-EFICE CUTTING MACHINE George 0. Langenberg, Ballwin, Mo., assignor of one-half to Elmer D. English, Clayton, Mo.

Application August 3, 1944, Serial No. 547,838

11 Claims.

This invention relates to cutting machines; and it has special reference -to mechanism for positively preventing the machine from Vrepeating; that is, positively preventing the machine from performing another unintended operation, or a series of unintended operations, after one o-peration of the machine has been initiated by the operator.

The machine in which the invention is embodied comprises a die block or table upon which the Work or material to be cut is placed and supported preparatory for and during cutting operations. Cutting dies of selected forms and shapes are operated by a head beam operatively supported above the die block or table and separated therefrom `by a horizontal space in which the work or material to be cut and the cutting dies are properly located and placed upon said die block or table. An intermittently rotative shaft is supported below the die block or table and operates eccentrics for actuating the head beam to drive the dies into and through the Work or material on the die block or table, which supports the cutting dies in said space. The said shaft is rotated intermittently through one complete revolution only, by driving mechanism operatively connected with said shaft by devices optionally actuated by the operator, and automatically dis'- connected from said shaft at the end of each complete revolution thereof. ating mechanism is disconnected from said shaft at or about the time that said shaft completes revolution. It is important that said shaft be stopped at the end of each complete revolution in order to afford the operator opportunity and time to replace the work or material and the cutting dies for another operation of the head beam. It sometimes occurs that the driving mechanism is not operatively disconnected from said shaft at the end of each revolution of said shaft. This results in repeating operations of the machine-that is, in more than one operation effect* y 'ed bymore `than one complete revolution of said shaft, more than one successive operation of said headbeam, and more than one operation of the cutting die's by the head beam. This causes accidents, sometimes seriously" injuring the hands of 'the operator extended into said space for the purpose of relocating the Work and the dies `properly for another operation of said head beam by said shaft. In many instances, these injuries to the `operator are serious.

IObjects of the present invention are to provide mechanism for preventing these repeating operations and thereby avoiding liability of acci- That is, the operdents and injuries to the operator; to provide means Vfor positively. disconnecting thedriving mechanism from the intermittently rotativeshaft and for positively preventing accidentalrotation of the shaft as required to operate the head beam; to provide an abutment for positively stopping said shaft at the end of each complete revolution regardless lof any tendency to repeat; to Vpro-- vide connections movable yby the 'operator for displacing said abutment to permit rotation of said shaft, `and simultaneously connecting said driving Vmechanism vwith said `shaft to Arotate `the flatter through another complete revolution `and thereby operate said head block and cutting die`s; to provide means for automatically Adisabling and disconnecting said connections from :said abutment during rotation of said 'shaft 'and regardless of the tendency of the driving mechanism tozperform a repeating operation of said shaft; and, generally, to equip Vthe machine with safety 'applances for the prevention of accidents and injuries to lthe operator.

Another object of the invention is to provide fa cutting machine having 1an intermittently rotative driving shaft, a `constantlyrotating Vpulley supported on or in axial `alinement with said `pul ley, a device keyed to and movable from asta tionary position on said shaft toward and intoengagement wiht said pulley whereby said vpulley will rotate said shaft, and then movable `along said shaft to a position out of engagement with said pulley to leave said pulley -in rotation While said shaft remains stationary, lever mechanism for optional operation by the operator to ymove said device into engagement with said pulley,` and means for operating said lever mechanism to move said device `out of engagement with said pulley, in combination with means for positively stopping rotation of said shaft by said pulley -or otherwise at the -endof each lcomplete revolution of said shaft, and 'means for preventing another or a repeating operation -of said shaft by said pulley until said lever mechanism lhas been returned to its initial starting position and has again been actuated by the operator.

Another object `of the invention is yto provide a cutting machine having an intermittentlyV 'rotative shaft, and optionally operative devices for rotating said shaft intermittently, in combination With lever connections for operating said devices optionally, and means for intermittently coupling said connections with and unc'oupl-ing the same from said devices as an incident to their optional operation to control effective intermittent frot'aftion of said shaft and to stop rotation of 'said shaft positively at the er'd of each' complete revolution.

Other objects will be made evident by the following description, reference being made to the annexed drawings, in which- Fig. 1 is a rear side elevation of a machine embodying my present invention, parts being broken away and removed to disclose other parts of said machine. s

Fig. 2 is an end elevation of the machine showing the constantly rotating driving pulley in axial alinement with the driving shaft.

Fig. 3 is a vertical sectional view on the line 3--3 of Fig. l looking in the direction of the arrows, showing parts of the devices for controlling intermittent rotation of the driving shaft.

Fig. 3a is a sectional view of a clutch device for imparting intermittent rotary movements to the shaft that operates the head -beam bythe constantly rotating pulley.

Fig. 4 is a vertical sectional view on the line 4-4 of Fig. l looking in the direction indicated by the arrows, showing the devices for positively stopping rotation of the driving shaft at the end of each complete revolution.

Fig. 5 is an enlarged sectional view on the line 5 5. of Fig. 4 looking in the directie-n indicated by the arrows on said line, which is the opposite direction from the direction indicated by the arrows on the sectional line of Fig. ,4.

Fig. 6 is a sectional view looking downwardly on the line 6-6 of Fig. 5, showing in plan elevation the devices for positively stopping movement of the driving shaft at the end of each complete revolution.

Fig. 7 is a sectional view on the line 'I-l of Fig. 6 looking toward the left as indicated by the arrows, showing the means for disconnecting the treadle device from the driving control mechanism and from the abutment that positively stops the driving shaft at the end of each complete revolution.

Fig. 8 is a perspective view of the abutment device for positively stopping the driving shaft at the end of each complete revolution, and for 0perating the member on the driving shaft into engagement with the axially alined constantly rotating driving pulley which imparts intermittent rotation to said drivingshaft.

` The cutting machine in and with which my present invention is embodied and combined comprises two relatively rigid horizontally spaced complementary frames I and 2. The frames I and 2 are upright and are rigidly connected together by a rear bar 3 and a front bar 4, attached to said frames by bolts 5. A vertically adjustable die block beam '8 extends horizontally between the frames I and 2 and has vertical screwthreaded sockets I on its ends extending outwardly through vertically elongated slots 8 insaid frames I and 2. vertically .spaced bearing bosses 9 are integral with the outer sides of said respective frames I and 2 above and below the slots 8 so that said sockets 'I extending through said slots 8 are between said respective pairs of bearing bosses. Die block adjusting screws I0 are rotatively supported in the bearing bosses 9. There is one adjusting screw I0 for each frame I and 2. The adjusting screws I0 are screwed through the sockets l' and thereby support the die block beam 6. A hand wheel II is attached to the upperY end of each adjusting screw I0 whereby said adjusting screws III are prevented from downward longitudinal displacement and may be rotated and caused to move the die block beam 6 vertically to different adjusted positions in the machine. A die block or block beam 6 and is rotatively supported by the pulley continues to rotate.

frames I and 2. Each end of the head beam I 3 is attached to and supported by a pair of vertical rods I5 mounted for vertical sliding movements in bearings I 6 rigid With the frames I and 2. Vertical sliding movements of said rods I5 will move the head beam I3 downwardly toward and upwardly from the die block or table I2. In the upper positions of the rods I5, the head beam, i3 is separated from the die block or table l2 byA au space II which is unobstructed both at the front and the rear and is large enough to receive the hands of the operator in placing the work or material upon the die bl-ock'or table and' in locating the dies in proper position on said Work or material. c

An eccentric I8 (Fig. 3) is attached to the shaft I4 for rotation thereby adjacent to each ofthe frames I and 2. A cross-head I9 is attached to the lower end of each pair of rods I5 below the lower bearings I6 and below the shaft I. An eccentric arm or pitman rod 28 is operatively engaged with each eccentric I8 and has its lower end connected with the adjacent crosshead I by a pivot ypin 2I. It is evident that, when the shaft I4 is rotated, it will rotate the eccentrics I8, operate the arms or pitman rods 29, move the rods I5 vertically in their bearings i6, and thereby move the head beam I3 downwardly toward and upwardly from the die block or table I2. It is also evident that a downward and upward movement of the head beam I3 will occur during each complete revolution of the shaft I4. The normal or c idle or unoperated position of the shaft I4 is that in which the high points of the eccentrics I8 eX- tend upwardly to support the head beam I3 in its uppermost position,rleaving the space Il -open and unobstructed so that the operator may place his hands in said space to locate the Work or material to be cut and the cutting dies. It is evident that any considerable or nearly complete downward movement of the head beam i3 during the time that the hands of the operator are over the top or top edge of a die in the space Il will crush or cut the hands and severely injure the operator.

A constantly running pulley 22 is supported on or in axial alinement with the shaft I 4. Said pulley is constantly rotated by a driven belt 23. A shiftable device 2li of kno-wn clutch construction is keyed on the shaft Id for sliding movements into engagement with the constantly running pulley 22 in order torotate the shaft I4 and for sliding movement out of engagement Ywith said pulley to leave the shaft I4 stationary while the Any suitable known type of clutch may be used for this purpose. A lever 25 has its lower end connected withthe shif table device Y2li and its upper end pivoted to a link 26 movable longitudinally in one direction to operate the lever 25 and thereby shift' the device 24 into engagement with the rotating pulley 22 to ro-tate the shaft .'ILI; and movable longitudinally in the opposite direction to shift said device 24 out of engagement with said pulley 22, leaving the pulley 22 in rotation while the shaft I4 stops and remains stationary. Y

brake wheel 21 is attached to the opposite `end of `the shaft I4 from the pulley 22 and is encircledby a brake shoe 28. Links 29 are operatively connected with the ends of the brake shoe 28and are operative to grip,` that is to set, said brake shoe -on and release the same from braking engagement with the wheel 21. The lower ends 'of the rods 29 have operative connection 30 (Fig. 1) with a shaft 3| supported for rocking movel `ments by the lower rear portions of the frames `I Vand 2. In its initial or starting position, the shaft 3I` holds the brake band 28 grip-ped or set Aupon the brake wheel 21. When the shaft 3l is turned in a `clockwise direction (Figs. 3 and 4), which is in Ya counter-clockwise direction as shown in Figs. 2 land 5, the connections 30 operate the rods 29 to release the brake band 28 from braking engagement with the brake wheel 21, leaving the shaft I4 freely rotative without restraint by the brake. When the shaft 3I is turned in a counterclockwise direction to its initial or starting position as shown in Figs, 3 and 4, or in a clockwise `direction as shown in Figs. 2 and 5, the rods 29 are operated to grip or set the brake band 28 on the brake wheel 21 and threby stop rotation of the Vshaft I4. On some occasions, as during a suddenly arising looseness at the brake co-nnection, it occurs that the shaft 3l is not returned to its initial or starting position and does not grip or set the brake to prevent rotation of the shaft I4; or that the brake mechanism does not function properly to prevent said rotation of said shaft I4. When the shaft I4 is not stopped at the end of each complete revolution, the eccentrics I8 on said shaft and the mechanism operated by said eccentrics I8 cause a repeat operation of` the head beam I3. This repeat operation is dangerous and has often resulted in serious injuries when the hands 4of operators are extended into the spaceA I1 for the purpose of manually adjusting the work or material and the dies for another operation of the head beam of the machine. The use of gripping pliers with long handles to adjust the work or material and place the dies thereon for another operation of the head beam of the machine is unsatisfactory for the reason that repeat operations frequently jar the dies to undesired parts of the work or material, with the result that the material is marred. My invention positively stops rotation of the shaft. I4 at the end of each co-mplete revolution. It cooperates directly with the brake mechanism and with the actuating link 26 to stop said shaft I4 in event of failure of the device 24 'to function properly, or in event of failure of the operator to release the control treadle, as hereinafter explained.

A pair of bell crank levers are mounted on pivots 32 supported by the rear bar 3. Upwardly extended arms V33 of said bell crank levers are pivotally connected to and support the link 26 for longitudinal movements as required to operate the lever 25. Horizontal arms 34 of said bell crank levers are pivotally connected with the upper ends of links 35 and 36, the-lower ends of which are pivotally connected to the forward ends of levers 31 rigidly attached to the rock shaft 3l. By these connections, the shaft 3| is rocked in synchronism with longitudinal movement of the link 26, and vice versa. It is impossible for the shaft 3l t0 rock without simultaneous horizontal longitudinal movement of the link 26, if joints at 35 and 36 and the bell crank arms 34 hold Properly.

The link 36 supports a pin 38 engaging into a slot 39 in the -rear end of a member 49 -constitute ing a combined actuator or operating lever for the link 36 and an abutment for stopping rotation of the shaft I4 at the -end of each complete revolution. The member 4U is pivoted on a support 4I attached to a Vbracket 42 rigidly secured to the bars 3 `and 4. The forward end of the member v4l! is actuated downwardly by a spring 43 having its lower end engaging said member 40 and its upper Vend engaging a holder 44. The spring 43 functions to operate the member 46 as required to move the link 36 upwardly and thereby turn the shaft "3| to its initial or starting position and set the brake `mechanism 21-28 as above described; and also to move the link 26 as required to shift the device 24 out of engagement with the pulley 22, thus leaving said pulley in rotation while the vshaft I4 remains stationary.

A treadle shaft 45 is supported by the lower ends of the frames I and 2 for rocking move'- ments. Treadle arms 46 extend forwardly from rigid attachment with said shaft 40 and support a treadle board 41 beyond and adjacent to the front sides o-f the frames I and 2. Springs 43 connect the arms 46 with the front beam 4 vand operate to raise the treadle device and thereby turn the treadle shaft 45 to its initial or starting position after each operation. An arm 49 has its lower end pivoted to one of the treadle arms 46, lextends upwardly through an opening 50 in the bracket 42 at the side of the member 45 rearwardly beyond the support 4I. The upper end of said link 49 is formed with a shoulderA 5! arranged to engage and disengage a lug 52 rigid with the member 46. When the shoulder 5! is in engagement with the lug 52, it is evident that downward movement of the treadle board 41 will move the lower end of the member 46 downwardly, thereby actuating the link 36 in a downward direction and turning the shaft 3l in a direction to release the brake band 28 from the brake wheel 21, and will also move the link 26 toward the right (Fig. l) to engage the device 2,4 with the constantly rotating pulley 22 as required to rotate the shaft I4 and operate the head beam i3. It is also evident that, when the shoulder 5I is disengaged from the lug 52, the spring 43 can operate the member 40 to raise the link 36 and thereby turn the shaft 3l in a direction to set the brake mechanism 21-23 and also move the link 26 longitudinally toward the left (Fig. l) in a direction to probably move the device 24 out of engagement with the constantly running pulley 22. This will enable the shaft I4 to be probably stopped at the end of a complete revolution, and will probably prevent the machine from repeating An eccentric carn 53 is attached to the shaft I4 and is provided with a radial shoulder 54 arranged to engage against an abutment 55 on the forward end of the member 40 when necessary to do so to prevent the machine from repeatingthat is, to stop the shaft I4 at the end of each complete revolution and prevent said shaft from turning more than one complete revolution. In the normal or starting position of the shaft I4, the shoulder 54 is separated from the abutment 55 by anarrow space 56 so that there is no frictional resistance to the operation of the member 4i) by the treadle mechanism ll6--41, etc. However, when the brake 21--28 fails to function to stop rotation of the shaft I4 by the constantly running pulley 22 at the end of each complete revolution of said shaft, or the device 24 fails to disengage the pulley 22, the abutment 55 will be engaged by the shoulderV 54 of the eccentric 53 and positively stop and prevent further repeat operation of said shaft I4 while forcing the friotional contact of the clutch members.

The shoulder 5I is disengaged from the' lug 52 at or near the end of downward movement of the treadle device 46-41 and very shortly before the end of a complete revolution of the shaft I4. An eccentric cam 5'I is attached to said shaft I4 adjacent to the eccentric 53, and has a high point 56. A rod 59 mounted for longitudinal movements in a support has its forward end adjacent to the eccentric cam 5l and its rear end adjacent to a part 6I on the link 49. A spring 62 actuates the rod 59 forwardly toward the eccentric cam 5l. The high part '58 on the eccentric cam 5lis arranged to engage against the rod 56 very shortly before and near the end of each complete revolution of the shaft I4. Therefore, just before and near the end of each complete revolution of .said shaft I 4, the rod 59 Will be moved rearwardly far enough to disengage the shoulder 5I from the lug 52, leaving the spring 43 free to hold the abutment 55 against the peripheral surface of the eccentric 53.V When the shoulder 54 strikes the abutment r55 very shortly after the end of each complete revolution of the shaft I4, further rotation of said shaft I4 will be positively stopped regardless of any failure of the brake mechanism 2'I-28 to function and regardless of the position of the device 24. However, when the brake mechanism 21-28 functions properly, and when the device 24 is disengaged from the constantly running pulley 22, the shaft i4 should be stopped-by said brake mechanism at the end of each complete revolution of said shaft,

leaving a slight space 56 between the shoulder 54 and the abutment 55. When the brake mecha- Vnisrn 27-28, and the driving mechanism 22-24 for the shaft I4, and other parts of the machine, are operating and functioning properly and in proper timed relationship, the shaft I4 is never turned more than one complete revolution; but said shaft I4 is stopped at the end of each complete revolution by action of the brake mechanism 2-28 and by the disengagement of the device 24 from the constantly running pulley. My mechanism presents or createsno resistance by engagement Vo-f the shoulder 54 with the abutment 55 when the machine is operating properly as described, for the reason that there should be a space 55 separating said shoulder 54 from said abutment y55 at the end of each complete revolution of the shaft I4. This invention does not increase the power required to drive the pulley 22 and the mechanism operated thereby.

The arm 49 is -actuated forwardly by a device 64 inY order to reengage the shoulder 5I with the lug 52 when the treadle mechanism 46-41 rises or is returned to its starting position by the springs 48.

In order to operate the machine, the treadle 4l is pressed downwardly in opposition to the power of the springs 48. Downward movement of the treadle 4l moves downwardly the arm 49, thereby moving downwardly the rear end of the member 45 and raising the abutment 55 above the shoulder 54. Downward movement of the rear end of the member 40 also moves downward- `ly the link 35, thereby turning the shaft 3| and moving the link 35 downwardly in synchronism with the downward movement of said link 36. Said downward movement of the links 35 and 36 simultaneously operates both bellV crank levers 33-34 and thereby moves the link 36 in a direction to engage the device 24 with the constantly running pulley 22 at about the same time that l ing each complete revolution of the shaft I4, the

head beam I3 is moved downwardly toward and j upwardly from the die block or table I2. Said downward movement of the head beam I3 forces any die or dies 'on the material or work downwardly to cut through said material or work.

Just before the-shaft I4 reaches the end'of each complete revolution,.as aforesaid, the eccentric cam 51-58 moves the rod 59 far enough toward the rear (Fig. to dis-,engage the shoulder 5I from the lug 52. When the shoulder 5IV is disengaged from the lug 52, the spring 43 immediately presses the abutment 55 against and into engagement with the eccentric cam 53 in front of the shoulder 54. This movement of the mem- 25 ber 46 operates the link 36 to turn the shaft 3| in a direction to set the brake shoe 23 upon and against the brake wheel 2'I at about the same time that the device 24 is disengaged from the constantly running pulley 22 by operation of the bell crank levers 33-34, the link 26, and the lever 25 by said links 35 and 36. The shaft Id'cannot again be rotated until the treadle mechanism 45e-47 is raised to its initial or starting position by the springs 48, nor until the arm 49 is returned shoulder 5I is again engaged with the lug 52 on the member 40.v These actions occur at each operation of the treadle mechanism -4'I, so

that it is impossible for the machine to perform 40 a repeating operation and hurt or injure the hands of the operator extending into the space I'I. The head beam I3 cannot operate or be operated until and unless the treadle mechanism 46-47 is again operated. Thus, unintended repeat operations of the machine are positively prevented.

From the foregoing, it is evident thatthisinvention attains al1 of its intended objects and purposes of positively preventing repeat operations of the head beam I3 by the intermittently rotative shaft I4. Should the brake mechanism 2'I-28, or the device 24, fail to function properly to stop the shaft I4 at the end of each complete revolution, or should the operating mechanism for the b-rake 21-28, or the device 24, fail to operate properly, rotation of the shaft I4 will positively be stopped atk or near the end of each-complete revolution as desired, and unintended dangerous and harmful repeat operations thereof and the head beam I3 will be prevented. I am aware that the inventionmay be varied in the construction and arrangement of the parts, and that the desired result may be attained by other equivalent elements and parts without departure from the nature and principle of the invention as defined by the appended claims.

I claim: 1. In a cutting machine having a device for operating cutting dies, and a rotary shaft supported for intermittent rotary movements of one complete revolution only during each of said movements and having operative connection with said device; .a continuously rotating pulley on said shaft, connections movable from a starting position for ycontrolling rotation of said shaft. by

to its initial or starting position, nor until the f saidI pul1ey,an abutment. device for positively preventing .moreA than one complete. revolution of saidshaft, a treadle` controlling said connections and said abutment device to leave said shaft rotative by said pulley, and a spring for moving said abutment device to position to prevent more than one complete revolution of said shaft by said pulley and for moving said connections to saidv starting position.

2. In a cutting machine havingl a device for operating cutting dies, and a rotary shaft supported for intermittent rotary movements of one complete revolution only during4 each of said movements and having operative connection with said device; a continuously rotating pulley on said shaft for imparting said intermittent rotary movements to said shaft, brake mechanism for stopping said rotary movements of said shaft at the end of each complete revolution thereof, connections movable from a starting position for releasing said brake mechanism and for controlling rotation of said shaft by said pulley, an abutment` device for positively preventing more than one complete revolution of said shaft, a treadle for moving said abutment device and also moving said connections from said starting position to leave `said shaft freely rotative by said pulley, and` a, spring for moving said abutment device to` position to prevent more` than one complete revolution of said shaft by said pulley and for moving said connections to said starting position independently of said treadle.

3. In` a cutting machine having a device for operating cutting.. dies, and a rotary shaft supported for intermittent rotary movements of one complete revolution only during each of said movements and having operative connection with said device; mechanism at one end of said shaft for imparting said intermittent rotary movements thereto, brake mechanism in connection with said shaft for stopping rotary movement` thereof at the end of each complete revolution, a treadle, an abutment device operated by said treadle, connections operated by said abutment device when said abutment device is operated by said treadle for releasing said brake mechanism and causing said first mechanism to impart said intermittent rotary movements to said shaft, and a spring for moving said abutment device to a position to prevent more than' one complete revolution of said shaft by said first mechanism and to set said brake mechanism.

4, In a cutting machine having a device for operating cutting dies, and a rotary shaft supported for intermittent rotary movements of one complete revolution only during each of said movements and having operative connection with said device; a continuously rotating pulley on said shaft, connections movable from a starting position for controlling rotation of said shaft by said pulley, a treadle, a coupling device operated directly by said treadle and engaging said connections for actuating and moving said connections from said starting position to rotate said shaft by said pulley as aforesaid, and means for disengaging said coupling device from said connections during each of said intermittent rotary movements of said shaft.

5. In a cutting machine having a device for operating cutting dies, and a rotary shaft supported for intermittent rotary movements of one complete revolution only during each of said movements and having operative connection with said device; a continuously rotating pulley on said shaft, connections movable from a starting posicomplete revolution of said shaft at each inter-A mittent rotary movement thereof by said pulley.

6. Ina, cutting machine having a device for operating cutting dies, and a rotary shaft supported for intermittent rotary movements of one complete revolution only during each of said movements and having operative connection with said device; a continuously rotating pulley on said shaft, connections movable from a starting position for controlling rotation of said shaftby said pulley, a treadle, a coupling device operated by said treadle and engaging said connections for moving said connections from said starting position as aforesaid, means for disengaging said coupling device from said connections during each of said intermittent rotary movements of said shaft, an abutment device for positively preventing more than one complete revolution of said shaft at each intermittent rotary movement thereof by said pulley, and a spring for moving said abutment device to position to prevent more than one complete revolution of said shaft by said pulley as aforesaid and for moving said connections to said starting position.

7. In a cutting machine having a rigid die block, a movable head beam having astarting position above and separated from said die block by an intervening space for receiving the work and the dies, and also the hands of the operator adjusting said dies on said work preparatory for downward movement of said'head beam, a shaft supported below said die block for intermittent rotary movements of one complete revolution only during each of said movements, and devices operated by said shaft for moving said head beam downwardly toward and upwardly from said die block toV operate said dies; a releasable clutch device settable to impart said rotary movements to said shafty a treadle, elements movable by said treadle from a starting position for directly and positively setting said clutch device to impart said rotary movements to said shaft, brake mechanism for stopping said rotary movements of' said shaft at the end of each complete single revolution thereof, a movable member for moving said elements to said starting position and thereby releasing said clutch device and also positively stopping and preventing more than one complete revolution of said shaft when said brake mechanis-m fails to stop said shaft, and an actuator for moving said member as aforesaid.

8. In a cutting machine having a rigid die block, a movable head beam having a starting position above and separated from said die block by an intervening space for receiving the work and the dies, and also the hands of the operator adjusting said dies on said work preparatory for downward movement of said head beam, a shaft supported below said die block for intermittent rotary movements of one complete. revolution only during each of said movements, and devices operated by said shaft for moving said head beam downwardly toward and upwardly from said die block to operate said dies; a constantly rotating pulley, a clutch device on said shaft for engagement with said pulley to impart said rotary movementsto said shaft and for disengagement from said pulley to leave said shaft stationary while saidpulley continues to rotate, a

treadle, elements movable by said treadle from a starting position for engaging said clutch device and said pulley, brake mechanism for stopping said rotary movements of said shaft at the end of each said complete revolution thereof when said clutch device and said pulley are disengaged., a shoulder rigid with said shaft, an abutmentmovable to a position for engagement by said shoulder and directly and positively stopping rotation of said shaft at the end of each said complete revolution of said shaft, and means for moving said abutment to position for engagement by said shoulder and for operating said elements to disengage said clutch device from said pulley and also to set said brake mechanism'to stop said shaft.

9. In a cutting machine having a rigid die block, and a movable head beam having a starting position above and separated from said die block by an intervening space for receiving the work and the dies, and the hands of the operator adjusting said dies on saidwork preparatory for downward movement of said head beam; a shaft supported below said die block for intermittent rotary movements of one complete revolution only during each of said movements, devices operated by said shaft for moving -said head beam downwardly toward and up-wardly from said die block to operate said dies during each of said rotary movements of said shaft, a constantly rotating pulley, a clutch device shiftable to a position to rotate said shaft by said pulley and to another position to leave said pulley in rotation while said shaft remains stationary, brake mechanism settable to stop rotary movements of said shaft at the end of each complete revolution thereof, elements movable from a starting position to shift said clutch device to said position to rotate said shaft-by said pulley and also to release said brake mechanism and leave said shaft freely rotative, a treadle, separable connections for moving said elements from 'said starting position by said treadle, devices operable independently of both said head beam and said treadle for moving said elements to said starting position to shift said clutch device to said second position, leaving said pulley in rotation while said shaft is free to stop and for setting said brake mechanism to stop said shaft, an actuator operating independently of bo-th said head beam and said treadle for operating said devices as aforesaid, and a shoulder rigid on said shaft for engagement with said last named devices for positively stopping said shaft at about the end of each 'complete revolution thereof regardless of the position of said clutch device and regardless of whether said brake mechanism stops said rotary movement of said shaft. Y

l0. In a cutting machine having a device for operating `cutting dies, and a rotary shaft supported below said device for intermittent rotary movements o-f one complete revolution only during each of said movements, and connections operated by said shaft for operating said device; a continuously rotating pulley, means cooperative with said pulley for imparting to said shaft in-termittent rotary movements of one complete revolution only, brake mechanism operating in synchronism with said means to release Vsaid shaft when said shaft is to be rotated by said pulley and said means and to stop said shaft at about the end of each complete revolution thereof, elements movable from a starting position for effecting cooperative engagement of said means and said pulley to rotate said shaft, a treadle, a connection engaged with said elements and operative by said treadle to move said elements from said starting position as aforesaid, means operated by said shaft for disengaging said connection from said elements, and mechanism operated in synchronism with said means and said brake mechanism and independently of said treadle and said brake mechanism for positively preventing more than one complete revolution of said shaft when said brake mechanism fails to stop said shaft.

11. In a cutting machine having a device for operating cutting dies, and a rotary shaft supported for intermittent rotary movements of one complete revolution only during each of said movements and having operative connection with said device; a continuously rotating pulley, means cooperative with said pulley and said shaft for imparting to said shaft intermitten-t rotary movements of one complete revolution only, brake mechanism for stopping said shaft and operative in synchronism with said means to release said shaft when said shaft is to be rotated by'said pulley and said means and to stop said shaft at about the end of each complete revolution thereof, elements movable from a starting position for operating said means and said brake mechanism i-n synchronism as aforesaid, a treadle, connections operated by said treadle for moving said elements from said starting position, and means operating independently of said rst named device for moving said elements to said starting position and also for positively preventing more than one complete revolution of said shaft. Y

GEORGE O. LANGENBERG. 

